Dip tubes

ABSTRACT

The present invention relates to a device that is adapted to be placed inside a container and to permit the continuous dispensing of a liquid stored in a container by enabling the fluid to be drawn from the interior of the container into the device and from the device to the outlet of the container. The device has a body which defines an internal chamber, an inlet through which liquid may be drawn into the chamber, and an outlet through which liquid can be drawing out of the chamber. The inlet of the device is adapted to restrict the access of liquid to the chamber when the device is inverted from a upright position. The present invention also relates to a dip tube and various container assemblies that are likewise adapted to permit the continuous dispensing of a liquid stored in a container.

The present invention relates to improvements in or relating to dip tubes for use in pressurised and non-pressurised containers to permit fluid to be drawn to, and dispensed through, an outlet of the container during use.

Nozzle arrangements are often fitted to, or over, the outlet valves of pressurised fluid filled containers, such as, for example, a hand-held aerosol canister. Such nozzle arrangements typically comprise an actuator portion that can be depressed by an operator to cause the outlet valve of the container to open and thereby actuate the release of fluid stored in the container through the nozzle arrangement. Similarly, nozzle arrangements provided with a manually operable pump or trigger actuator which operates a pump chamber in order to cause fluid to be dispensed through the nozzle arrangement (hereinafter referred to as “pump or trigger actuated nozzle arrangements” or just “pump or trigger nozzle arrangements”) are also widely used in conjunction with non-pressurised containers. Pump or trigger-actuated nozzle arrangements are fitted to an outlet opening of the container, typically by means of a screw thread, and enable a fluid present in the container to be dispensed through the nozzle arrangement by the operation of the pump or trigger actuator.

The fluid products stored in containers are usually various forms of liquid and, to enable the liquid product stored in the container to be drawn to, and dispensed through, a nozzle arrangement during use, it is known to provide a dip tube positioned inside the container. A typical dip tube has a free or open end disposed proximate to the bottom of the container and an opposing end which is typically connected to the outlet valve (in the case of pressurised containers) or directly to the pump or trigger actuated nozzle arrangement (in the case of non-pressurised containers). During use, i.e. following the operation of the actuator of the nozzle arrangement, the liquid product is drawn into the dip tube from the bottom of the container through its free/open end, and along the dip tube to the outlet valve of the container, or the pump or trigger actuated nozzle arrangement (in the case of non-pressurised containers) where it is dispensed from the container.

These conventional dip tubes function well if the liquid is being dispensed while the container is upright. This is because the free/open end of the dip tube is positioned at the bottom of the container where it is immersed in the liquid product and will remain so until all, or nearly all, of the product had been dispensed. However, problems can arise when the container is inverted or tilted during use because the liquid product present is the container will flow towards the inverted or tilted upper end of the container under the influence of gravity and this may leave the free end of the dip tube extending into an upper fraction of gas (which may be air at atmospheric pressure in the case of a non-pressurised container, or compressed air or an alternative gaseous propellant in the case of a pressurised container). As a consequence, the operation of the nozzle while the container is inverted or tilted can result in the expulsion of this gas rather than the liquid product stored in the container. This creates a problem because it disrupts the dispensing of the desired liquid product. Furthermore, it is a particular problem when the container is a pressurised container and compressed air or gas is used as the propellant because the expulsion of this air or gas instead of the liquid product results in the depletion of the propellant from the container. Ultimately this can result in the exhaustion of the propellant before all the product present in the container has been dispensed, which is clearly undesirable.

For these reasons, it is an object of the present invention to provide a simple and inexpensive means for enabling a liquid product stored within a container to be dispensed continuously through a nozzle arrangement fitted to an outlet of the container, even if the container is held at an angle where the open end of the dip tube is not usually immersed in the product (i.e. when it is shaken, tilted or inverted), or when the product is product stored in the container is nearly exhausted.

It is a further object of the present invention to provide a device, container and modified dip tube in which the expulsion of gas or air instead of product is minimised while the container is inverted, shaken or held at a tilted orientation.

According to a first aspect of the present invention there is provided a device adapted to be placed inside a container and to permit a liquid stored in said container to be drawn from the interior of the container into said device and from said device to the outlet of the container where it is dispensed through a nozzle arrangement, said device having a body which defines an internal chamber, an inlet through which liquid may be drawn into said chamber, and an outlet through which liquid can be drawn out of said chamber;

-   -   wherein said inlet is adapted to at least restrict the access of         liquid to said chamber at least when said device is inverted         from an upright position.

The expression “upright position” is used herein to denote an orientation which the device assumes when it is suspended in a container by its outlet and can hang freely. In preferred embodiments of the invention the outlet is positioned on the upper surface of the device and the inlet is positioned on the bottom of the device. Hence, the upright position in such cases will be the orientation assumed by the device when it is suspended by its outlet and hangs freely with the inlet forming the bottom or lowermost part of the device.

Preferably, the inlet is further adapted to at least restrict the access of liquid when said device is tilted or shaken.

By “tilted”, we mean that the device is displaced from the upright position, but is not full inverted, i.e. it orientation is some where between a fully upright or fully inverted position.

It is especially preferable that the inlet is adapted to at least restrict access to said chamber when said device is tilted so that the inlet is no longer immersed within liquid present within said container.

In certain embodiments of the invention, the device is adapted to at least restrict access to the chamber when the device is titled through ninety degrees or more from the upright position.

It has been found that the utilisation of the device of the present invention circumvents, or at least minimises, the problem of gas or air being dispensed through the outlet of the container instead of the product when the device is inverted or tilted so that the inlet is not immersed in the product present in the container. Specifically, the chamber of the device enables a reservoir of the product present the container to be stored within the device. This reservoir of product is available for dispensing regardless' of the orientation of the device (and hence, the container in which it is placed). Furthermore, the provision of an inlet which is adapted to restrict access to the chamber at least when the device is inverted or held at a tilted angle where the inlet is not immersed in the product prevents, or at least minimises, the volume of gas or air that can be drawn into the device and, ultimately, dispensed through the nozzle arrangement during use. Accordingly, an operator using a container with the device of the present invention placed inside will not notice any significant difference in the quantity of product dispensed through the outlet when the container if it is operated while the container is inverted, upright, shaken or held at a tilted orientation.

The device of the present invention may be placed within any suitable container which is provided with a nozzle arrangement to actuate and control the release of the product stored in the container. It shall be appreciated, therefore, that the container may be a non-pressurised container which is provided with a pump or trigger-actuated nozzle arrangement fitted to its outlet. In such cases, the outlet of the device is usually connected to the nozzle arrangement so that liquid drawn through the device during use passes directly into the nozzle arrangement when the trigger or pump actuator is operated. Alternatively, the container may be a pressurised container provided with a valve at its outlet (hereinafter referred to as an outlet valve) having a nozzle arrangement fitted to the container which has an actuator adapted to releasably engage with the outlet valve to open it and actuate the release of the liquid product stored in the container. In this case, the outlet of the device is adapted to be connected to the internal surface of the so that, when the outlet valve is open, liquid is drawn to the outlet valve through the device of the present of the invention. In some cases the propellant present in the pressurised container will be a compressed gas, such as compressed air, which is a particularly desirable propellant to use.

The chamber of the device may be prepared from a rigid material. For example, the wall of the chamber may be in the form of a bellows, which can collapse inwards to reduce the volume of the chamber when fluid is drawn out of the chamber through the outlet faster than it is replenished through the inlet during use, and then return to its original non-deformed configuration and thereby cause liquid to be drawn into the chamber through the inlet Preferably, however, at least a portion of said body forming a wall of said chamber is resiliently deformable and configured to assume a resiliently biased or “non-deformed” configuration in the absence of any pressure differential between the chamber and the external environment and deform inwards to a collapsed configuration and thereby reduce the volume of the chamber when the pressure within the chamber is lower than the external pressure. This enables the resiliently deformable portion of the wall of the chamber to deform inwards and cause the volume of the chamber to decrease as product is drawn out of the chamber during use and subsequently return to its original resiliently biased configuration and drawn in more liquid through the inlet. It is especially preferred that the entire wall of the chamber is resiliently deformable. Most preferably, the entire body of the chamber is resiliently deformable.

Any suitable resiliently deformable material may be used, such as a flexible rubber or flexible plastic material (e.g. flexible polyethylene of polypropylene compositions).

The device of the present invention may be readily manufactured by conventional moulding techniques and as such are relatively inexpensive to produce.

Prior to its initial insertion into the container, it is preferable to crush the device so that, once it is placed inside the container, it will return to its original “non-deformed” configuration and, in doing so, will draw the product from the container into the chamber of the device ready for use. The body may be pleated to enhance the crushing of the device.

Preferably, when the device is placed in a container, the inlet of the device is adapted to be positioned proximate to the bottom of the container in a similar manner to the opening of a standard dip tube. This results in fluid being drawn into the device from the bottom of the container and enables virtually all of the product stored in the container to be drawn into the device and dispensed through the nozzle arrangement.

The inlet of the device is adapted to restrict access to the chamber at least when the device is inverted from an upright position during use (i.e. when the container in which it is placed is inverted). It shall be appreciated that the opening of the inlet will invariably become exposed to the gas fraction present in the container when it is tilted or inverted, and hence, the inlet serves to restrict the amount of gas that may access the device and thus, be expelled through the nozzle arrangement under these circumstances.

In its simplest form the inlet of the device comprises a constricted opening. By “constricted opening” we mean that the opening defined by the inlet has a maximum dimension which is less than that of the outlet of the device so that the flow into the chamber through the inlet is less than the flow which is possible through the outlet. In some embodiments, the inlet will be a fine hole formed in the wall of the chamber. In other embodiments, the inlet of the device may comprise a tube which is open to the chamber at one end and the constricted opening may be disposed at any position along the length of the tube. The constricted opening impedes the flow of gas or air into the device when the container is inverted or tilted so that the inlet is not immersed in any liquid present in the container. Preferably, the constricted opening reduces the flow through the inlet to between 0 and 20% of the flow which is possible through the outlet. More preferably, the constricted inlet is adapted to restrict the flow through the inlet to between 1 and 10% of the flow which is possible through the outlet. Most preferably, the constricted inlet is adapted to restrict the flow through the inlet to between S and 10% of the flow which is possible through the outlet. This is achieved by controlling the relative sizes of the constricted inlet opening and the outlet, i.e. it is preferable that the inlet is between 1 and 20%, more preferably 1 and 10%, and most preferably 5 and 10%, of the size of the outlet. Accordingly, when the liquid is being dispensed through the container it is usually drawn from the reservoir held within the chamber of the device faster than it can be replaced with either more product present in the container (if the inlet opening is immersed in the product) or gas or air (if the product is inclined at an angle where the inlet is not immersed in the product). In preferred embodiments where the chamber has a resiliently deformable wall, the wall will deform inwards and the volume of the chamber will reduce if the product is dispensed through the outlet of the chamber at a rate which is faster than it is replenished by the contents of the container through the inlet. Once the release of fluid from the container ceases, the container, and hence the device placed therein, will usually be returned to its upright position in which the inlet will be immersed in the liquid stored in the container. As the chamber deforms back to its resiliently biased configuration, liquid from the container will be drawn into the chamber of the device through the inlet. Although a proportion of the gas present in the container may still access the chamber of the device if the inlet is not immersed in the product, i.e. if the device is tilted, shaken or inverted, the provision of a reservoir of product at least ensures that a proportion of the product will be dispensed and the provision of the constricted opening ensures that the amount of gas expelled through the outlet will be significantly reduced when compared with a standard dip tube.

It is preferred, however, that the inlet comprises a valve which is adapted to close off the inlet to form at least a partial seal when the device is inverted or tilted through 90 degrees or more from the upright position, and open the inlet when the device is placed in the upright position (when the inlet is normally immersed in the product at the bottom of the container).

Preferably, the valve is adapted to completely seal the inlet when the device is inverted or tilted through 90 degrees or more from the upright position.

Any suitable valve may be used. Preferably, the valve comprises a cavity defined by the inlet, said cavity having a ball (e.g. a ball bearing) or other moveable body retained therein and being configured such that said ball or other moveable body occupies a first position within the cavity when said device is upright and becomes displaced to a second position when said device is inverted or tilted, whereby said valve is open when said ball or other moveable body is in the first position and said valve at least partially closed when said ball or other moveable body is in the second position. Usually, the first position is a lower position and said second position is nn upper position and said ball or other body moves between said lower and upper positions by the effect of gravity.

Preferably, the valve is completely closed when the ball or other moveable body is in the second position.

Accordingly, when the container and the device are upright, the ball bearing resides in the first or lower position in the cavity defined by the inlet and the actuation of the release of the contents of the container by the operation of a nozzle at the outlet of the container results in product being drawn into the device through the inlet and passing through the chamber and the outlet of the device into the nozzle arrangement. In effect, the device functions just like a standard dip tube in this position. However, when the device is inverted, or tilted through 90 degrees or more from the upright position so as to cause the movement of the ball bearing or similar structure to the second/upper position within the cavity under the influence of gravity and thereby form a seal in the inlet, then the influx of liquid product or gas/air (depending whether or not the inlet is immersed in the liquid product) is restricted.

The provision of a partial or complete seal of the inlet will result in liquid being expelled through the outlet of the chamber of the device at a greater rate than the rate at which the contents of the container are drawn into the chamber through the inlet. Hence, in embodiments where the chamber has a resiliently deformable wall, this will cause the resiliently de-formable wall to be sucked inwards, effectively reducing the internal volume of the chamber. Once actuation of the release of the product is terminated by stopping the operation of the nozzle arrangement, then the elastic recoil forces present in the resiliently deformed walls of the chamber will create a vacuum pressure within the chamber which in turn generates a suction force in the inlet to the device. This suction force can cause the ball or similar body to be retained in the second/upper position once the device is returned to its upright standing position. For this reason, it is also preferable that the valve is provided with means to dislodge the ball or other moveable body from the second position back to the first position when said device is returned to the upright position.

In certain embodiments of the invention, the means for dislodging the ball is the provision of a partial seal when the ball or other moveable body is in the second position. This permits a degree of leakage to occur around the ball or body and enables contents of the container (which is usually product if the container is stood upright and the inlet is immersed in the product) to access the chamber of the device to equalise any pressure differential that may exist. Hence, once the suction force has been removed, the ball or other body will become dislodged from the second position. The pressure differential will usually be equalised once the resiliently deformable wall of the chamber has retained it original non-deformed or resiliently biased configuration.

Preferably, the amount of leakage through the partial seal is between 1 and 20% of the flow possible through the outlet of the device. Most preferably, the amount of leakage through the partial seal is between 5 and 20% of the flow possible through the outlet of the device.

If the partial seal is only weak then the ball or other body could be dislodged to the first position by simply shaking the device/container, or it may just drop back to the first position by the effect of gravity.

The provision of a partial seal may be preferable when the product contained within the container is a product that is likely to block or clog the valve during use. Examples of such products include various polishes, paints, starches etc. The recess comprising the ball bearing is much less likely to block or clog during use and every time the ball bearing moves any residue that has built up and will become dislodged.

Alternatively, the means for dislodging the ball or other moveable body may be a leak provided in some other part of the device.

The ball valve may also be provided with an alternative means for ensuring that the ball is dislodged when the device is returned to the upright position after use at a tilted/inverted angle. One example of such a means involves the provision of a small protrusion or post in the internal wall of the valve of the device which, when the ball is in the upper position, either pushes the ball away (towards the lower position) or pushes between the ball and the internal wall of the valve as the chamber/device collapses during use.

Alternatively, the device may be configured so that once it is virtually empty the deformation caused in the device either pushes the ball out from the partial seal position or deforms the valve in the vicinity of the ball so that it can fall back to its original position in which the valve is open under the influence of gravity.

If the inlet is either in the form of a constricted opening or comprises a valve capable of forming only a partial seal, it is possible that a small amount of gas may access the device when the container is inverted, tilted or shaken, although it will still be significantly less than if the partial seal was not formed. For example, if an aerosol canister can spray 1 millilitre/second through its outlet and is usually used for between 3 and 5 seconds per actuation, then it will be possible for gas to be expelled through the outlet at the same rate when the dip tube is not immersed in the product. However, if the inlet is adapted to restrict access to the chamber when the container is tilted or inverted to, for example, only 10% of that which is possible through the outlet of the device, then the amount of gas that can be ejected through the outlet of the container during actuation is only 0.1 millimetres/second, i.e. the amount of gas that could be ejected through the nozzle is effectively reduced by 90%. In practice, the actual amount of gas expelled through the outlet in preferred embodiments of the invention where the entire device is formed from a flexible material will be much less because, by virtue of the weight of the liquid present in the chamber, the device will tend to remain immersed in the liquid product present in the container, especially when the container is only tilted slightly from the upright position. For example, if the container is placed on its side, then the device will tend to float on the surface of the liquid product and the weight of the liquid present in the device tends to cause the lower inlet end to be submerged in the liquid.

However, as previously mentioned, it is especially preferred that the valve forms a complete seal to prevent any gas or air being expelled when the container is tilted or inverted.

In addition to, or instead of, either of these aforementioned forms of inlet, an alternative valve could be provided at the inlet. A suitable example of one such additional valve is a so-called “flap valve”. It is especially preferred that the flap of said valve is weighted and adapted to move under the influence of gravity between an initial position in which the valve is open when the device is upright and a position in which the valve is closed when the device is inverted or tilted. In certain preferred embodiments of the invention the inlet is a tube and the open end of said tube through which fluid accesses the tube during use forms the weighted flap which is adapted to hang downwards when the device is upright so at to form an open tube and fold over when the device is inverted so as to form a kink at a position along the length of the inlet tube when the device is inverted or tilted, said kink forming at least a partial seal to prevent or minimise the ingress of fluid into the device while it is inverted or tilted. Effectively, the weighted end of the tube is adapted to fall over and form a kink in the inverted inlet tube to form a seal in the tube when the device is inverted, and fall back to form an open tube when the device is returned to the upright position. It is preferable that a complete seal is formed by the kink in the inlet tube, rather than just a partial seal.

The outlet of the device may enable the product to be drawn from the bottom or the top of the chamber of the device when the container (and hence, the device) is in the upright position. In some embodiments of the invention the outlet of the device is an opening in the chamber wall that can receive a dip tube which connects the chamber of the device with the outlet of the container. In other embodiments, the outlet is an open end of an outlet tube, which is integrally formed with the device, and is open to the chamber at one end and connected to the container outlet at the other end.

In certain preferred embodiments of the invention, the body of the device may define two or more separate chambers. A first chamber of said chambers will be as defined above and possess the inlet and outlet, whereas a second of said chambers will posses an outlet. The second chamber may just have an outlet or may further comprise an inlet so that fluid may be drawn into the second chamber. It is generally preferred that the second chamber is a sealed chamber only having an outlet and a fluid product, which may be a liquid or a gas, can be placed in the second chamber and drawn out through its outlet in a similar manner to the way fluid is drawn from the first chamber. The outlets of the first and second chambers may join so that the fluid drawn out of each chamber mix with each other before reaching the outlet valve or nozzle arrangement of the container. Alternatively, the outlets of each chamber may be separate and each outlet may form a separate connection with the outlet valve or pump or trigger nozzle arrangement In the case of pressurised containers, the fluid from each chamber may mix within the outlet valve or within a nozzle arrangement fitted to thereto. In the case of non-pressurised containers, the contents of each chamber may be mixed within the pump or trigger actuated nozzle arrangement. Alternatively, the fluids may be ejected separately from the nozzle arrangements.

The dimensions of the outlets of said first and second chambers can be modified to control the relative rates at which fluid is drawn from each chamber.

The two or more chambers of the device may be separate, adjacent to one another or arranged in any other suitable configuration. In a preferred embodiment of the invention a first chamber is surrounded by a second chamber in a concentric arrangement.

In situations where the device is placed in a pressurised container, such as hand-held aerosol canister, it is desirable for the second chamber to contain a propellant in certain cases. The propellant can mix with the liquid drawn from the first chamber and can assist the atomisation of the liquid into small droplets. In such cases, it may be preferable to provide a constricted opening, such as a fine hole, in the wall of the device so that gas present in the container can be slowly drawn into the second chamber from the container when it is in the upright position (i.e. the opening must be positioned above the liquid level in the upright position). This will enable the propellant depleted from the second chamber during use to be replenished with more propellant from the interior of the container.

In certain embodiments of the invention, the chamber is divided into two separate compartments, an upper compartment and a lower compartment, with a hole formed in the interface between them. Preferably, the hole formed in the interface is sufficiently small to restrict the movement of the contents of the chamber between the upper and lower compartments when the container (and hence, the device) is inverted. It is also preferable that the lower compartment is three to four times the size of the upper compartment. In such embodiments, it also preferred that the inlet of the device is a tube which opens into the upper chamber of the device so that the contents of the container that are drawn into the chamber through the inlet initially access the upper chamber. It is also preferred that the outlet of the device is a tube which is open to the chamber at the bottom of the lower compartment and extends upwards from the device to form a connection with the outlet of the container. Preferably, the outlet tube is provided with a hole positioned approximately half way up the chamber, which connects the interior of the chamber to a position along the length of the outlet tube. The significance of this hole is discussed further below in reference to FIG. 1 of the accompanying drawings.

The device of the present invention can be placed inside a container instead of, or as an attachment to, a standard dip tube. Accordingly, the present invention also provides, in a further aspect, a dip tube comprising a device as defined herein fitted thereto.

Preferably, however, the device is fitted to the end of the dip tube via its outlet, i.e. the dip tube forms the connection between the chamber outlet and the outlet of the container. Where this is the case, the outlet of the device may be in the form of a tube which connects to the end of the dip tube or, alternatively, an opening in the chamber which is adapted to receive the end of the dip tube. Alternatively, the device may be connected directly to the container outlet and the dip tube may be connected to the inlet of the device.

According to a further aspect of the present invention there is provided a pressurised container having an interior in which a liquid may be stored, an outlet valve, a nozzle arrangement having an actuator adapted to selectively engage and open said outlet valve upon operation and thereby actuate the release of liquid under pressure, wherein said container comprises a device as defined herein placed therein and fitted to said outlet valve via its outlet so that fluid is drawn from said device when said actuator of said nozzle arrangement is operated.

According to a further aspect of the present invention there is provided a pressurised container having an interior in which a liquid may be stored, an outlet valve, a nozzle arrangement having an actuator adapted to selectively engage and open said outlet valve upon operation and thereby actuate the release of liquid stored therein under pressure, wherein said container comprises a dip tube as defined herein placed therein and fitted to said outlet valve so that fluid is drawn from said dip tube when said actuator of said nozzle arrangement is operated.

According to a further aspect there is provided a non-pressurised container having an interior in which a liquid may be stored, an outlet having a pump or trigger actuated nozzle arrangement fitted thereto and comprising a device as defined herein placed therein, said device being connected to said nozzle arrangement via its outlet such that liquid is drawn into said nozzle arrangement from said device when the trigger or pump actuator is operated.

According to a further aspect of the present invention there is provided a non-pressurised container having an interior in which a liquid may be stored, an outlet having a pump or trigger actuated nozzle arrangement fitted thereto and comprising a dip tube as defined herein placed therein, said dip tube being connected to said nozzle arrangement via its outlet such that liquid is drawn into said nozzle from said dip tube when the trigger or pump actuator is operated.

According to a further aspect the present invention there is provided a container having an interior in which liquid may be stored, an outlet having a nozzle arrangement fitted thereto and a device placed in the interior of the container, said device being adapted to permit a liquid stored in said container to be drawn from the interior of the container into said device and from said device to the outlet of the container where it is dispensed through a nozzle arrangement, said device having a body which defines an internal chamber, an inlet through which liquid may be drawn into said chamber, and an outlet through which liquid can be drawn out of said chamber;

-   -   wherein said device is suspended in said container by its outlet         so that it can swing within the container as it is tilted or         inverted.

Preferably, the device is as defined above.

The suspension of the device permits the device to swing within the container. Therefore, the device, by virtue of the weight of the liquid present in the chamber, will tend to remain immersed in any liquid product present in the container, especially when the container is only tilted slightly from the upright position. For example, if the container is placed on its side, then the device will tend to float on the surface of the liquid product and the weight of the liquid present in the device tends to cause the lower inlet end to be submerged in the liquid.

According to a further aspect the present invention there is provided a pressurised container having a sealed interior, an outlet valve, an internal wall defining an internal compartment positioned at or proximate to the bottom of the interior of said container and a dip tube positioned within the interior of said container, said dip tube being connected to said outlet valve and extending from said valve to said internal compartment such that fluid is drawn to said outlet valve from said compartment when the outlet valve is opened, wherein said compartment further comprises an inlet through which fluid can access said compartment from the interior of the container, said inlet being further adapted to at least restrict the access to said compartment when said container is inverted.

According to a further aspect the present invention provides a non-pressurised container having an interior, an outlet with a pump or trigger actuated nozzle arrangement fitted thereto, an internal wall defining an internal compartment positioned at or proximate to the bottom of the container and a dip tube extending from said nozzle arrangement into said internal compartment such that fluid is drawn to said nozzle arrangement from said compartment when the pump or trigger actuator is operated, wherein said compartment further comprises an inlet through which fluid can access said compartment from the interior of the container, said inlet being further adapted to at least restrict the access to said compartment when said container is inverted.

The inlet may comprise a constricted opening or a valve, as defined above.

In a preferred embodiment, the inlet comprises a constricted opening formed around the dip tube where it extends into the compartment. The contents of the container may flow slowly from the remainder of the container into the compartment through this constricted opening. Preferably, the rate of flow is between 5 and 20% of the rate of flow through the dip tube.

The inlet is preferably positioned so that it is immersed in any liquid present in the container while the container is stood in its upright position.

Preferably, at least a portion of said internal wall defining said internal compartment is resiliently deformable and configured to assume a resiliently biased configuration in the absence of any pressure differential between the compartment and the interior of the container and deform inwards and reduce the volume of the compartment when the pressure within the compartment is lower than the pressure in the interior of the chamber. Most preferably, the entire internal wall of the chamber is resiliently deformable. The resiliently deformable wall may be made of any suitable resiliently deformable material, as described above.

The compartment may be formed across the entire bottom of the container or just a portion thereof. It is especially preferred that the compartment extends across the entire bottom of the interior of the container and the internal wall forms the bottom or floor of the remainder of the interior of the container.

During use, the contents of the compartment are drawn to the outlet through the dip tube during use in response to the opening of the outlet valve or, in the case of a non-pressurised container, the operation of the pump or trigger of the nozzle arrangement. As the contents of the compartment are drawn into the dip tube, the resiliently deformable wall will deform inwards, effectively reducing the volume of the compartment, because the rate at which the product is replenished with the contents of the container will be less than that rate at which it is drawn out through the dip tube. After use, the container is returned to the upright position and liquid is then drawn into the compartment from the interior of the container to through the inlet. This replenishment will continue until the resiliently deformable wall returns to its initial resiliently biased or “non-deformed” configuration.

If the container is tilted, shaken or inverted, then liquid will still be dispensed through the outlet during use because the liquid present in the compartment is prevented from leaking out into the remainder of the container to any significant degree by the constricted opening. Furthermore, the influx of any gas or air from the container into the compartment while the container is tilted, inverted or shaken (and the inlet of the compartment is not immersed in the product present in the container) is also minimised by the constricted opening.

The container may comprise two or more internal compartments. Each compartment may be provided with a separate dip tube or receive a branch of a single dip tube.

It has also been found that the problem of maintaining the continuous release of product from a container when it is shaken or held at an angle where the open end of the dip tube is not immersed in the product can also be minimised by using a modified dip tube.

Hence, the present invention also provides, in a further aspect, a container having an interior in which a liquid may be stored during use, said container comprising an outlet having a manually-operable pump or trigger actuated nozzle arrangement fitted thereto and a dip tube positioned in the interior of said container, said dip tube having an inlet end through which fluid present in the container may access the dip tube and an opposing end which is connected to the nozzle arrangement so that liquid stored in the container can be drawn to, and dispensed through, the nozzle arrangement following the operation of the pump or trigger, wherein the internal volume of the dip tube is at least five times the volume of product that is dispensed through the nozzle arrangement following a single full actuation.

It shall be appreciated that by “full actuation” we mean that trigger or pump of the nozzle device is actuated to its maximum extent so that the maximum possible volume of product is dispensed through the nozzle in response to a single actuation.

Conventional dip tubes fitted to pump or trigger nozzle devices typically have an internal volume that is, at most, only one to two times the volume that is dispensed through a pump or trigger nozzle following a single full actuation. This low internal volume is specifically desired by manufacturers of pump and trigger spray devices because it reduces the number of actuations of the pump or trigger required to initially fill the dip tube before the liquid product can be dispensed through the nozzle. As a consequence, however, only a limited volume of liquid product can be retained within the dip tube and this will be rapidly exhausted if the nozzle device is operated while the container is held at an angle where the open end of the dip tube through which the contents of the container are drawn is not immersed in the product present in the container, i.e. if the nozzle device is actuated while the container is shaken, inverted or tilted. However, it has been found that providing a dip tube with a volume that is at least five times the volume dispensed through the nozzle device following a single full actuation enables the product to be dispensed through the nozzle for longer periods when the open end of the dip tube is not immersed in the product.

It will be appreciated that if the container remains inverted, for example, then air present in the container will eventually be ejected through the nozzle instead of product once the product stored in the dip tube has been exhausted. For this reason, the internal volume of the dip tube is preferably sufficient to store enough of the product therein to enable above average usage of the product concerned. Hence, the volume required will vary depending on the type and nature of the product, but it should be at least five times the volume of product which is dispensed through the nozzle following a single full actuation for each case.

Preferably, the internal volume of the dip tube is between fifteen and twenty times the volume of product that is dispensed through the nozzle arrangement following a single full actuation so that at least twenty full actuations of product can be dispensed if the container is held at an angle where the end of the dip tube is not immersed in the product present in the container. It is especially preferred that the volume is between twenty and thirty times the volume the volume of product that is dispensed through the nozzle arrangement following a single full actuation.

The open end of the dip tube is preferably positioned proximate to the bottom of the interior of the container so that it is immersed in the liquid product stored therein when the container is upright. However, if the container is held at an angle where the end of the dip tube is not immersed in the product present in the container, it will be appreciated that some air present in the container will be drawn into the dip tube following each actuation of the pump or trigger nozzle. This air can be replaced with product by returning the container to its upright position whereby the open end of the dip tube will be immersed in the liquid product present within the container and operating the pump or trigger actuated nozzle arrangement to draw more of the liquid product into the dip tube and expel any air present therein.

This mode of operation is not desirable, however, and for this reason, it is preferable that that the open end of the dip tube through which the contents of the container are drawn into the dip tube during use is adapted to restrict access to the dip tube at least when the device is held at an angle where the open end of the dip tube is not immersed in the product present in the container, i.e. when it is tilted, inverted, or shaken. Hence, it especially preferred that the inlet end of the dip tube comprises a constricted opening or valve arrangement as hereinbefore defined.

The dip tube is preferably resiliently deformable, although it may be formed of rigid material (but would not work as well). This provides two main advantages. Firstly, it enables the dip tube to move within the container under the effect of gravity, which means that the dip tube will, at least to a certain extent, tend to follow and remain immersed within the product present in the container as the container is tilted, shaken or inverted. Secondly, by collapsing the resiliently deformable tube before it is initially placed into the container, then the product present in the container can be drawn into the dip tube as it returns to its original resiliently biased /“non-deformed” configuration and hence, the dip tube is filled ready for the first use.

In yet a further aspect of the present invention there is provided a dip tube adapted to be placed inside a pressurised container having an interior adapted to store a liquid therein and an outlet valve, said dip tube having an inlet end through which the contents of the container are drawn into the dip tube during use and an opposing end which is adapted to be connected to the outlet valve of the container, wherein the inlet end of the dip tube is adapted to at least restrict access of fluid into the to the dip tube when the dip tube is inverted from an upright position.

Conventional dip tubes used in pressurised containers only have a small internal volume and hence, any product present therein is rapidly exhausted if the container is held at an angle where the open end of the dip tube is not immersed in the product present in the container into which it is placed. Preferably, the dip tubes of the present aspect of the invention has an internal volume sufficient to enable at least five seconds of continuous actuation of liquid product to be dispensed, even if the container is held at an angle where the open end of the dip tube is not immersed in the product present in the container in which it is placed.

Of course, it will be appreciated that once the product stored in the dip tube is exhausted when the container is inverted, for example, then gas or air present in the container may be ejected instead of product. For this reason, the internal volume of the dip tube is preferably sufficient to retain sufficient product therein to enable above average usage of the product while the container is inverted, tilted or shaken. Hence, the volume required in practice will vary depending on the application.

Preferably, the internal volume of the dip tube is sufficient to enable between ten and twenty seconds of continuous actuation if the container is held at and angle whereby the open end of the dip tube is not immersed in the product, with an internal volume sufficient to enable between ten and forty seconds of continuous use being especially preferred.

As previously discussed herein, the provision of the an inlet end of the dip tube which is adapted to restrict access to the dip tube at least when the device is held at an angle where the open end of the dip tube is not immersed in the product present in the container, i.e. when it is tilted, inverted, or shaken, limits the amount of gas or air that accesses the dip tube while the open end thereof is not immersed in the product present in the container into which it is placed. Hence, it is preferred that the inlet end of the dip tube is provided with either a constricted opening or, more preferably, a valve arrangement as hereinbefore defined.

The dip tube may be crushed prior to its initial insertion into the container so that, once placed in the container, it returns to its original “non-deformed” configuration and in doing so it fills up with product already present in the container.

The dip tube is also preferably resiliently deformable, as discussed above, although it may be prepared from rigid material.

How the invention may be put into practice will now be described by way of example only in reference to the accompanying drawings in which:

FIG. 1 is a cross sectional view of a first embodiment of a device of the present invention, in diagrammatic form;

FIG. 2 is a cross sectional view of a second embodiment of a device of the present invention, in diagrammatic form;

FIG. 3 is a cross sectional view of a third embodiment of a device of the present invention, in diagrammatic form;

FIG. 4 is a cross-sectional view of a fourth embodiment of a device of the present invention, in diagrammatic form;

FIG. 5A is an external view of a fifth embodiment of the device of the present invention, in diagrammatic form;

FIG. 5B is a perspective view of the device shown in FIG. 5A;

FIG. 5C is a perspective view of the outlet end of the device shown in FIG. 5A; and

FIG. 5D is a perspective view of an adaptor for fitting the outlet end of the device shown in FIG. 5C to a nozzle arrangement or outlet valve of a container.

In the following description of the Figures, like reference numerals are used to denote like or corresponding parts in different Figures.

FIG. 1 shows a first embodiment 101 of a device according to the present invention, which is adapted to be placed inside a container and to permit a liquid stored in said container to be drawn from the interior of the container into said device and from said device to the outlet of the container where it can be dispensed through a nozzle arrangement (not shown).

The device 101 is formed from a flexible and resiliently deformable plastic material and comprises a body which defines an internal chamber 102, an inlet 103 having an opening 103 a through which the contents of said container may access the interior of the chamber, and an outlet tube 105, which connects the device to an outlet valve or pump or trigger actuate nozzle arrangement so that liquid can be drawn from the chamber 102 to the outlet of the container (not shown).

The chamber 102 comprises an upper compartment 102 b and a lower compartment 102 a. The compartments are linked by a constricted aperture 102 c to enable a restricted flow of fluid to occur between them.

The outlet tube 105 extends through an aperture 104 formed on the upper surface of the device and the aperture 102 c into the lower compartment 102 a of the chamber where its inlet end 105 a is positioned. The opposing end of the outlet tube 105 is connected to the container outlet (not shown) so that fluid is drawn out of the device from the bottom portion of the lower compartment 102 a to the outlet during use.

The inlet 103 is comprises a ball valve, which consists of an internal cavity 103 b having a ball bearing 103 c present therein. The ball bearing 103 c is capable of movement between a lower position in which the inlet 103 is open and an upper position in which sit in the opening 103 d and forms a seal. Movement between the lower and upper positions occurs by the effect of gravity when the device is inverted or tilted from its upright position (as shown in FIG. 1). Hence, when the device is tilted or inverted so that the ball bearing 103 c moves to the upper position, the inlet becomes sealed and this prevents the ingress of gas or air from the container in which the device 101 is placed.

When the container and hence the device 101 placed therein are upright, fluid is dawn into the device through the inlet and accesses the chamber 102, where it is then drawn through the outlet tube to the outlet/nozzle arrangement of the container. If the container is inverted or tilted, the ball bearing 103 c becomes displaced from the lower position to the upper position and seals the inlet 102, thereby preventing any gas or air in the container to which the inlet has become exposed from accessing the chamber 102. Fluid can continue to be drawn from the chamber 102 through the outlet tube 105, so product can still be dispensed from the container. If the dispensing of liquid from the container continues while the device is inverted of tilted so that the inlet is sealed, the walls of the chamber will resiliently deform inwards to effectively reduce the volume of the chamber 102. Once the dispensing of fluid ceases and the container and the device 101 are returned to the upright position the ball bearing can be dislodged back to the lower position and liquid can be drawn into the chamber 102 as the resiliently deformed wall returns to its initial resiliently biased or non-deformed configuration to replenish that which has been dispensed.

The reduced pressure within the chamber 102 caused by the resiliently deformable wall can result in the ball bearing 103 c becoming stuck in the upper position. For this reason, the ball bearing may have to be dislodged from the upper position by a suitable means. The cavity can be shaped around the opening 103 d so that the ball bearing 103 c is only weakly held in the upper position and thus can readily drop down when it is returned to the upright position. The ball may also be dislodged by simply shaking the container and hence, the device placed therein, to cause the ball to drop down to the lower position. Alternatively, the cavity could be arranged so that there is a small leak around the ball bearing 103 c so that some liquid can seep through the seal into the chamber to equalise the pressure differential, although this is generally not preferred because small amounts of gas or air could seep into the chamber when the device is inverted or tilted.

The opening 103 a is preferably positioned adjacent to the bottom surface of the container into which it is placed so as to enable virtually all the product stored in the container to be drawn through the device during use. A further length of tube may be fitted to the opening of the inlet 103 a if necessary to achieve this objective.

The open end of the outlet tube 105 a is offset with respect to the inlet 102 so that any gas which accesses the chamber through the inlet (while the device is upright) rises up past the open end 105 a of the outlet tube and accesses the upper chamber 102 b through the fine aperture 102 c. If the container and the device placed therein are inverted or tilted, then the flow of any gas or air present in the upper compartment 102 b to the vicinity of the opening 105 a of the outlet tube 105 is impeded by the restricted aperture 102 c. Even if some gas is present and accumulates around the opening o 105 a of the outlet tube 105 when the device is inverted, at least some liquid product will still access the outlet tube 105 through the hole 106. Thus, some product at least will be continuously dispensed.

A second embodiment of the present invention is shown in FIG. 2. The device 201 shown in FIG. 2 is essentially the same as that shown in FIG. 1 except the inlet 103 is provided with a tube extension 202 which extends into the upper compartment 102 b. Hence, fluid drawn in through the inlet is introduced into the upper compartment 102 b and will access the lower compartment 102 a through the constricted aperture 102 c. The advantage of this construction is that any air or gas that does manage to access the device through the inlet will accumulate in the upper compartment 102 b when the device is upright. Furthermore, when the device 201 is inverted or tilted during use, the flow of gas towards the opening of the outlet tube 105 a is inhibited by the constricted opening 102 c. This arrangement would also prevent the device emptying under effect of gravity, which could theoretically occur with the device 101 shown in FIG. 1.

A simplified device 301 of the present invention is shown in FIG. 3. The device 301 has a chamber 102, which, unlike the embodiments shown in FIGS. 1 and 2, does not have upper and lower compartments, an inlet 103 and an outlet tube 105. As before, the outlet tube 105 extends into the bottom of the chamber 102. However, in a preferred form of this embodiment, the outlet tube does not extend into the chamber, but instead is merely received by the aperture 104, in a similar manner to the arrangement shown in FIG. 4 below. The outlet tube 105 is provided with a hole 106, the function of which is described above in reference to FIGS. 1 and 2. The inlet 103 in this embodiment comprises a constricted opening, which restricts the amount of product or gas (depending on whether the inlet is immersed in the product or gas) from the container that can be drawn into the chamber 102. In use, the contents of the chamber are drawn to the outlet of the container through the outlet tube 105. This causes the wall of the chamber 102 to resiliently deform inwards and effectively reduces the volume of the chamber because the contents of the chamber are not replenished at the same rate through the inlet 103. The chamber then returns to its original configuration after use and the contents from the container are drawn into the chamber 102 through the inlet 103. It will be appreciated that the constricted opening of the inlet 103 limits the amount of any gas, which may access the chamber 203 when the container and the device 301 placed therein is inverted. Likewise, however, the ingress of liquid while the container and hence, the device 301, are upright is also restricted. It may therefore take some time for the chamber 102 to refill. The dimensions of the constricted inlet opening can be selected to control the amount of time required, which may vary from application to application.

The hole 106 provided in the outlet tube of the aforementioned embodiments described in FIGS. 1 to 3 is preferable insofar as it improves the functioning of the device by ensuring that at least a proportion of the product is dispensed through the outlet at all times, but it shall be appreciated that the provision of such a hole is not essential and simpler devices could be prepared without this hole being present.

Furthermore, the outlet tube 105 could be a dip tube to which the device is attached.

A fourth embodiment of a device of the present invention is shown in FIG. 4. This device 401 is adapted to be fitted to the end of a dip tube 105 via its outlet 104. The dip tube 105 connects a resiliently deformable chamber 102 to an outlet of a container into which the device is placed (not shown). The chamber 102 is provided with an inlet 103 through which the contents of the container may access the interior of the chamber 102. The inlet 103 comprises a ball valve arrangement as previously described above.

In an alternative embodiment, the inlet 103 of the device 401 may be a constricted opening which serves to restrict the flow of the contents of the container into the interior of the chamber 102, as described in reference to FIG. 3.

A further alternative embodiment would comprise an outlet tube (equivalent to tube 204) which is provided with a resiliently deformable expanded end (bulrush) having a constricted opening thereto.

In yet a further alternative embodiment of the present invention, the device is in the form of a standard dip tube, equivalent to the dip tube 105, which is provided with an expanded chamber formed therein or fitted thereto. This chamber is provided with an inlet opening of equivalent dimensions to the bore of the dip tube. This device is especially suited for a connection to a pump or trigger nozzle device. During use, i.e. when the pump or trigger nozzle device is being operated to actuate the release of the contents stored in the container, liquid is drawn into the expanded chamber through the inlet and exits the chamber into the dip tube. If the device is subsequently inverted, tilted or shaken, then a reservoir of product stored in the expanded chamber will continue to be dispensed through the outlet following the operation of the pump or trigger nozzle device. After use, the product dispensed from the expanded chamber can be replenished by returning the container to an upright position in which the inlet of the expanded chamber is immersed in the product present in the container and the operation of the pump or trigger device causes the product to be drawn into the expanded chamber.

Another embodiment of the present invention comprises a separate internal compartment formed by placing a resiliently deformable wall in the bottom of the interior of the container. This compartment has an opening through which a dip tube extends to draw the contents of the compartment to the outlet of the container during use. A slow feed of the contents of the container into the or compartment is provided by a constricted inlet opening, i.e. a small gap, formed between the edge of the opening and the dip tube, which connects the compartment to the remainder of the interior of the container. The liquid product present in the container will flow into the separate compartment when the container is upright. If the device is tilted or inverted, the flow of product out of the compartment into the remainder of the container is restricted. Hence, the product should be continuously dispensed through the outlet. After use, the product dispensed from the compartment is replenished by the flow of fluid from the interior of the container into the compartment through the small gap.

Yet another alternative embodiment is shown in FIGS. 5A to 5C. This embodiment of the device 501 comprises an inlet 103, an internal chamber 102 and outlet end 104. The inlet 103 comprises a ball valve (not shown), which functions in an identical manner to the ball valves described above. In contrast to the previously described embodiments, however, a separate second chamber 502 is provided around the outside of the chamber 102, as shown in FIG. 5C. The chamber 102 and the second chamber 502 are arranged concentrically. The chamber 102 is exactly the same in principle as the chambers 102 of the previously described in reference to FIGS. 3 and 4. The second chamber 502, in contrast, is a sealed chamber, which does not have an inlet. Fluid can be placed in the second chamber 502 and then drawn out of the chamber together with the product drawn from the chamber 102. The contents drawn out of the first and second chambers may be mixed prior to entering the outlet valve or pump or trigger nozzle arrangement to which the device is attached, or, alternatively, the contents could mix within the outlet valve/nozzle arrangement, or even expelled separately. In the latter case, however, a separate pump chamber would be required for each chamber that is present in order to propel its contents to and through the nozzle arrangement. Varying the dimensions of the outlet of the second chamber 502 can control the rate at which fluid is drawn out of it during use. A narrow or constricted outlet will provide a slow rate of flow out of the second chamber, whereas a wider outlet will enable a higher flow to occur.

Fluid, from the second chamber may be drawn out by a venturi effect caused by fluid flowing from the chamber 102, or may be drawn directly by the opening of the outlet valve or the actuation of a pump or trigger actuator of a nozzle arrangement, depending on the circumstances of use.

The walls of both the chamber 102 and the second chamber 502 are resiliently deformable. However, the second chamber will gradually collapse over time because fluid is only drawn out of it and is not replenished in the same way as for the chamber 102.

The outlet end 104 of the device 501 is directly connected to an outlet valve of a pressurised container, or a pump or trigger nozzle arrangement (in the case of non-pressurised containers) by means of a suitable adaptor, such as the adaptor 510 shown in FIG. 5D. The adaptor 510 may be a separate article, which is fitted to the outlet end of the device 501, as shown in FIG. 5D, or, alternatively, may be integrally formed with either the device 501 or the outlet valve or pump/trigger nozzle arrangement to which it is to be attached.

The adaptor 510 is configured to be received within the outlet end 104 of the device 501. Referring to FIG. 5C (which only shows the upper portion of the device), it can be seen that support segments 505 are provided at the outlet end of the chamber 502. Theses support segments 505 provide greater rigidity to the resiliently deformable walls at the outlet end of the device 501, so that the necessary engagement between the adaptor and the outlet end of the device can be made. The adaptor 510 comprises a circular protrusion 511, which is received within the outlet end of chamber 502. An outlet aperture 512 is then aligned over the outlet end of the chamber 102. An additional outlet aperture may be provided so that fluid from the second chamber 502 may be drawn into the outlet valve or pump or trigger nozzle arrangement, or, alternatively, a passageway connecting this chamber to the outlet aperture 512 may be provided.

It shall be appreciated that the embodiments of the invention described in reference to the Figures are intended to be by way of example only and should not be construed as limiting the scope of the invention. 

1. A device adapted to be placed inside a container and to permit a liquid stored in said container to be drawn from the interior of the container into said device and from said device to the outlet of the container where it is dispensed through a nozzle arrangement, said device comprising: a body which defines an internal chamber, an inlet through which liquid may be drawn into said chamber, and an outlet through which liquid can be drawn out of said chamber; wherein said inlet is adapted to at least restrict the access of liquid to said chamber at least when said device is inverted from an upright position, wherein at least a portion of said body forms a wall of said chamber and is resiliently deformable and configured to: (i) assume a resiliently-biased configuration in the absence of any pressure differential between the chamber and the external environment and (ii) deform inwards and reduce the volume of the chamber when the pressure within the chamber is lower than the external pressure.
 2. A device according to claim 1 wherein the entire wall of the chamber is resiliently deformable.
 3. A device according to claim 1 wherein the entire body of the device is resiliently deformable.
 4. A device according to claim 1, wherein said inlet is further adapted to at least restrict the access of liquid when said device is tilted or shaken.
 5. A device according to claim 4, wherein said inlet is adapted to at least restrict access to said chamber when said device is tilted so that the inlet is no longer immersed within liquid present within said container.
 6. A device according to claims 4, wherein said device is adapted to at least restrict access to the chamber when the device is tilted through ninety degrees or more from the upright position.
 7. A device according to claim 1, wherein said inlet is a constricted opening configured to restrict the access of fluid to the chamber regardless of the orientation of the device.
 8. A device according to claim 7, wherein said inlet is a hole in the wall of the chamber.
 9. A device according to claim 7, wherein said constricted inlet is adapted to restrict the flow through the inlet to between about 0 and about 20% of the flow which is possible through the outlet.
 10. A device according to claim 9, wherein said constricted inlet is adapted to restrict the flow through the inlet to between about 1 and about 10% of the flow which is possible through the outlet.
 11. A device according to claim 9, wherein said constricted inlet is adapted to restrict the flow through the inlet to between about 5 and about 10% of the flow which is possible through the outlet.
 12. A device according to claim 1, wherein said inlet comprises a valve adapted to open the inlet when the device is upright and at least partially seals the inlet when the device is inverted.
 13. A device according to claim 12, wherein said valve is adapted to completely seal the inlet when the device is inverted.
 14. A device according to claim 12, wherein said valve comprises a cavity defined by the inlet, said cavity having a ball or other moveable body retained therein and being configured such that said ball or other moveable body occupies a first position within the cavity when said device is upright and becomes displaced to a second position when said device is inverted or tilted, whereby said valve is open when said ball or other moveable body is in the first position and said valve at least partially closed when said ball or other moveable body is in the second position.
 15. A device according to claim 14, wherein said valve is completely closed when the ball or other moveable body is in the second position.
 16. A device according to claim 15, wherein said first position is a lower position and said second position is an upper position and said ball or other body moves between said lower and upper positions by the effect of gravity.
 17. A device according to claim 1, wherein the valve is provided with a means to dislodge the ball or other moveable body from the second position back to the first position when said device is returned to the upright position.
 18. A device according to claim 17, wherein said means includes a partial seal when said ball or other moveable object is in the second position so that a degree of leakage can occur.
 19. A device according to claim 18, wherein the amount of leakage through the partial seal is between about 1 and about 20% of the flow possible through the outlet of the device.
 20. A device according to claim 19, wherein the amount of leakage through the partial seal is between about 5 and about 20% of the flow possible through the outlet of the device.
 21. A device according to claim 12, wherein said valve is a flap valve.
 22. A device according to claim 21 wherein the flap of said valve is weighted and adapted to move under the influence of gravity between an initial position in which the valve is open when the device is upright and a position in which the valve is closed when the device is inverted or tilted.
 23. A device according to claim 22, wherein said inlet is a tube and the open end of said tube through which fluid accesses the tube during use form the weighted flap which is adapted to hang downwards when the device is upright so at as to form an open tube and fold over when the device is inverted so as to form a kink at a position along the length of the inlet tube when the device is inverted or tilted, said kink forming at least a partial seal to prevent or minimize the ingress of fluid into the device while it is inverted or tiled.
 24. The device according to claim 1, wherein the inlet of said device is adapted to be positioned proximate or directly adjacent to the bottom of the container.
 25. A device according to claim 1, wherein the outlet is adapted to connect the chamber of the device to an outlet valve of said container or a nozzle arrangement fitted to said container.
 26. A device according to claim 25, wherein the outlet is adapted to enable said device to be fitted to a dip tube so that fluid drawn out of the chamber through said outlet during use flows through said dip tube to the outlet valve or inlet of a nozzle arrangement.
 27. A device according to claim 1 wherein said body defines a first chamber having said inlet and said outlet and a second chamber having an outlet through which fluid stored therein may can be drawn out of said second chamber.
 28. A device according to claim 27, wherein said second chamber further comprises an inlet so that fluid may be drawn into the second chamber.
 29. A device according to claim 27, wherein the outlet of said first and second chambers join so that the fluid drawing of said chambers mixes before it reaches the outlet of the container.
 30. A device according to claim 27, wherein said outlets are separate and each of said outlets is adapted to permit fluid to be drawn from each of said respective chambers to the outlet valve or nozzle arrangement fitted to the container.
 31. A device according to claim 27, wherein the dimensions of the outlets of said first and second chambers are modified to control the relative rates at which fluid is drawn from each chamber.
 32. A flexible dip tub comprising a device as claimed in claim
 1. 33. A dip tube as claimed in claim 32, wherein said device is fitted to an end of said dip tube by its inlet.
 34. A dip tube according to claim 32, wherein said device is fitted to an end of said dip tube at its outlet.
 35. A dip tube according to claim 34, wherein said outlet is an aperture adapted to receive said dip tube.
 36. A pressurized container having an interior in which a liquid is stored, an outlet valve, a nozzle arrangement having an actuator adapted to selectively engage and open said outlet valve upon operation and thereby actuate the release of liquid under pressure, wherein said container comprises a device as claimed in claim 1 placed therein and fitted to said outlet valve via its outlet so that fluid is drawn from said device when said actuator of said nozzle arrangement is operated.
 37. A pressurized container having an interior in which a liquid may be stored, at outlet valve, a nozzle arrangement having an actuator adapted to selectively engage and open said outlet valve upon operation and thereby actuate the release of liquid stored therein under pressure, wherein said container comprises a flexible dip tube as claimed in claim 32 placed therein and fitted to said outlet valve so that fluid is drawn from said dip tube when said actuator of said nozzle arrangement is operated.
 38. A non-pressurized container having an interior in which a liquid may be stored, an outlet having a pump or trigger actuated nozzle arrangement fitted thereto and comprising a device as claimed in claim 1 placed therein, said device being connected to said nozzle arrangement via its outlet such that liquid is drawn into said nozzle arrangement from said device when the trigger or pump actuator is operated.
 39. A non-pressurized container having an interior in which a liquid may be stored, an outlet having a pump or trigger actuated nozzle arrangement fitted thereto and comprising a flexible dip tube as claimed in claim 32 to 35 placed therein, said dip tube being connected to said nozzle arrangement via its outlet such that liquid is drawn into said nozzle from said dip tube when the trigger or pump actuator is operated.
 40. A pressurized container comprising: a sealed interior; an outlet valve; an internal wall defining a internal compartment positioned at or proximate to the bottom of the interior of said container, said internal compartment including an inlet through which fluid can access said compartment from the interior of the container; and a flexible dip tube positioned within the interior of said container, said dip tube being connected to said outlet valve and extending from said valve to said internal compartment such that fluid is drawn to said outlet valve from said compartment when the outlet valve is opened, wherein said inlet is adapted to at least restrict the access to said compartment when said container is inverted.
 41. A non-pressurized container comprising: an interior; an outlet with a pump or trigger actuated nozzle arrangement fitted thereto; an internal wall defining an internal compartment position at or proximate to the bottom of the container, said internal compartment including an inlet though which fluid can access said compartment from the interior of the container; and a dip tube extending from said nozzle arrangement into said internal compartment such that fluid is drawn to said nozzle arrangement from said compartment when the pump or trigger actuator is operated, wherein said inlet is adapted to at least restrict the access to said compartment when said container is inverted.
 42. A container as claimed in claim 40, wherein said inlet is further adapted to at least restrict the access of liquid when said device is tilted or shaken.
 43. A container according to claim 42, wherein said inlet is positioned so that it is usually immersed in said liquid when the container is upright.
 44. A container according to claim 42, wherein said inlet is adapted to at least restrict access to the compartment when the device is tilted through ninety degrees or more from the upright position.
 45. A container according to claim 40, wherein said inlet is a constricted opening configured to restrict the access of fluid to the compartment regardless of the orientation of the container.
 46. A container according to claim 45, wherein said inlet is a hole in the wall of the chamber.
 47. A container according to claim 45, wherein said constricted inlet is formed around the dip tube extending into the compartment.
 48. A container according to claim 40, wherein said inlet comprises a valve adapted to open the inlet when the device is upright and at least partially seal the inlet when the device is inverted.
 49. A container according to claim 40, wherein at least a portion of said internal wall defining said internal compartment is resiliently deformable and configured to assume a resiliently biased configuration in the absence of any pressure differential between the compartment and the interior of the container and deform inwards and reduce the volume of the compartment when the pressure within the compartment is lower than the pressure in the interior of the chamber.
 50. A container according to claim 49, wherein the entire internal wall of the chamber is resiliently deformable.
 51. A container according to claim 40, wherein said internal wall forms the bottom or floor of the remainder of the interior of the container.
 52. A container according to claim 40, wherein said container comprises two or more internal compartments, each compartment receiving a separate dip tube or receiving a separate branch of a single dip tube.
 53. A dip tube according to claim 32, wherein at least a portion of said tube is resiliently deformable and configured to assume a resiliently-biased configuration in the absence of any pressure differential between the interior of the dip tube chamber and the external environment and deform inwards and reduce the volume of the chamber when the pressure within the chamber is lower than the external pressure.
 54. A dip tube according to claim 53 wherein the entire dip tube is resiliently deformable.
 55. A dip tube according to claim 53, wherein the volume of the dip tube is sufficient to enable about 5 seconds of liquid to be continuously dispensed.
 56. A dip tube according to claim 53, wherein the volume of the dip tube is sufficient to enable about 10 to 20 seconds of liquid to be continuously dispensed when the dip tube is inverted.
 57. A dip tube according to claim 56, wherein the volume of the dip tube is sufficient to enable about 10 to 40 seconds of liquid to be continuously dispensed. 